1. Novel MOF(Zr)-on-MOF(Ce) adsorbent for elimination of excess fluoride from aqueous solution.
- Author
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Song, Jiangyan, Yu, Yongyi, Han, Xiaoshuai, Yang, Weisen, Pan, Wenbin, Jian, Shaoju, Duan, Gaigai, Jiang, Shaohua, and Hu, Jiapeng
- Subjects
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SORBENTS , *AQUEOUS solutions , *PORE size distribution , *FLUORIDES , *ELECTROSTATIC interaction , *ADSORPTION capacity - Abstract
Herein, we used a one-pot method to fabricate a novel MOF-on-MOF adsorbent, namely MOF(Zr)-on-MOF(Ce). The adsorbent demonstrated a high maximum fluoride-ions capture capacity of 164.47 mg g−1. The morphology, elemental distribution, pore size distribution, and thermal stability were studied using SEM-EDS, XRD, BET, and TGA. The influence of the temperature, solution pH, fluoride concentration, and coexisting ions was explored using intermittent experiments. The results suggested that MOF(Zr)-on-MOF(Ce) had a fast capture rate for fluoride. MOF(Zr)-on-MOF(Ce) maintained an excellent fluoride removal performance over a wide pH range with an initial fluoride concentration of 20 mg L−1. The optimal effect was obtained at a pH of 4, but a high removal efficiency of 94% was maintained even at a pH of 9. Interference experiments showed that only the PO 4 3– had an adverse inhibition influence. The field experiments demonstrated that MOF(Zr)-on-MOF(Ce) can keep the safety threshold levels of fluoride in drinking water. The Langmuir and pseudo-second order kinetic models were well fitted for the defluoridation process, demonstrating that the adsorption of fluoride ions on MOF(Zr)-on-MOF(Ce) was dominated by monolayer chemisorption. With the further characterization and kinetic thermodynamic studies indicates that the removal mechanism involves ion exchange, electrostatic interactions and complexation effect. [Display omitted] • A novel MOF(Zr)-on-MOF(Ce) adsorbent were fabricated via one-pot methods for defluorination. • The maximum adsorption capacity of MOF(Zr)-on-MOF(Ce) was 164.47 mg g–1 for F ions. • The adsorbent had an excellent defluoridation performance with a wide pH range. • The mechanisms are ion-exchange, electrostatic interaction and complexation effect. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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